Accelerated Inertial Regime in the Spinodal Decomposition of Magnetic Fluids
Abstract: Furukawa predicted that at late times, the domain growth in binary fluids scales as $\ell(t)\sim t{2/3}$, and the growth is driven by fluid inertia. The {\it inertial growth regime} has been highly elusive in molecular dynamics (MD) simulations. We perform coarsening studies of the Stockmayer (SM) model comprising of magnetic dipoles that interact via long-range dipolar interactions as well as the usual Lennard-Jones (LJ) potential. This fascinating polar fluid exhibits a gas-liquid phase coexistence, and magnetic order even in the absence of an external field. From comprehensive MD simulations, we observe the inertial scaling [$\ell(t)\sim t{2/3}$] in the SM fluid for an extended time window. Intriguingly, the fluid inertia is overwhelming from the outset - our simulations do not show the early diffusive regime [$\ell(t)\sim t{1/3}$] and the intermediate viscous regime [$\ell(t)\sim t$] prevalent in LJ fluids.
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